A model for the structure of fumarate reductase in the cytoplasmic membrane of Escherichia coli

By a recombinant DNA approach we have prepared Escherichia coli cytoplasmic membranes that are highly enriched in the terminal electron transfer enzyme fumarate reductase. This enzyme is composed of four nonidentical subunits in equal molar ratio. A 69,000-dalton covalent flavin-containing subunit and a 27,000-dalton nonheme iron-containing subunit make up a membrane extrinsic catalytic domain. Two very hydrophobic subunits of 15,000 and 13,000 daltons make up the hydrophobic membrane anchor domain. Electron microscopy of negatively stained membranes shows a characteristic knob-and-stalk-type structure composed of the catalytic domain. The anchor polypeptides have been analyzed for hydrophobic segments and alpha-helical content and a model for their organization within the lipid bilayer is presented. The results reviewed in this paper suggest a model for the fumarate reductase complex in the cytoplasmic membrane.     

Nucleotide sequence and comparative analysis of the frd operon encoding the fumarate reductase of Proteus vulgaris. Extensive sequence divergence of the membrane anchors and absence of an frd-linked ampC cephalosporinase gene

The fumarate reductase of Escherichia coli is a bioenergetically important membrane-bound flavoenzyme consisting of four subunits. A and B comprise a membrane-extrinsic catalytic domain whereas C and D are hydrophobic polypeptides which link the catalytic centres to the electron-transport chain. The nucleotide sequence of the frd operon encoding the fumarate reductase of the distantly related bacterium, Proteus vulgaris has been determined and used to predict the primary structures of the respective subunits. Extensive amino acid sequence identity (greater than 80%) was found between the fumarate reductase A and B subunits of P. vulgaris and E. coli. In contrast, the primary structures of the P. vulgaris and E. coli C and D proteins are much less closely related (about 60% homology) although the overall hydrophobicity of their three membrane-spanning segments has been conserved. In most enteric bacteria, the frd operon is followed by genes, ampR and/or ampC, required for the genetic regulation and biosynthesis of a cephalosporinase. The corresponding region of the P. vulgaris genome is occupied by an operon (orf A'BCD) containing at least four genes which are clearly unrelated to the ampC system. Intriguingly the primary structures of the OrfA and OrfD proteins suggest that, like fumarate reductase, they may be components of a membrane-bound enzyme complex involved in energy metabolism.     

Organization of dimethyl sulfoxide reductase in the plasma membrane of Escherichia coli.

Dimethyl sulfoxide reductase is a trimeric, membrane-bound, iron-sulfur molybdoenzyme induced in Escherichia coli under anaerobic growth conditions. The enzyme catalyzes the reduction of dimethyl sulfoxide, trimethylamine N-oxide, and a variety of S- and N-oxide compounds. The topology of dimethyl sulfoxide reductase subunits was probed by a combination of techniques. Immunoblot analysis of the periplasmic proteins from the osmotic shock and chloroform wash fluids indicated that the subunits were not free in the periplasm. The reductase was susceptible to proteases in everted membrane vesicles, but the enzyme in outer membrane-permeabilized cells became protease sensitive only after detergent solubilization of the E. coli plasma membrane. Lactoperoxidase catalyzed the iodination of each of the three subunits in an everted membrane vesicle preparation. Antibodies to dimethyl sulfoxide reductase and fumarate reductase specifically agglutinated the everted membrane vesicles. No TnphoA fusions could be found in the dmsA or -B genes, indicating that these subunits were not translocated to the periplasm. Immunogold electron microscopy of everted membrane vesicles and thin sections by using antibodies to the DmsABC, DmsA, DmsB subunits resulted in specific labeling of the cytoplasmic surface of the inner membrane. These results show that the DmsA (catalytic subunit) and DmsB (electron transfer subunit) are membrane-extrinsic subunits facing the cytoplasmic side of the plasma membrane.     

Limited proteolysis of nitrate reductase purified from membranes of Escherichia coli.

The heterogeneous form of nitrate reductase released from the membrane fraction of Escherichia coli by heat treatment was converted to a new electrophoretic form by incubation with trypsin. As a result of the trypsin treatment, the heat-released enzyme was converted from an associating-dissociating system to a nonassociating monomer (Mr approximately 200,000) which retained full enzymatic activity. Several distinct subunits in the 47,000- to 59,000-dalton range were converted to a single 43,000-dalton subunit during the trypsin treatment, while the other major subunit (155,000 daltons) was unaffected. Nitrate reductase extracted from the membrane fraction with deoxycholate and ammonium sulfate was composed of two apparently homogeneous subunits (155,000 and 59,000 daltons). The detergent-extracted enzyme preparation was converted by trypsin to an electrophoretic form very similar to the product of trypsin treatment of the heat-released enzyme with an identical subunit composition (155,000 and 43,000 daltons). These results demonstrate that the heterogeneous subunits present in the heat-released enzyme are produced during heat treatment by proteolytic cleavage of a single 59,000-dalton subunit. The fragments removed by trypsin treatment are implicated in the self-associating properties of the heat-released enzyme.     

Assembly of Escherichia coli fumarate reductase holoenzyme

The production and assembly of the four fumarate reductase polypeptides into holoenzyme was studied in vivo in a T7-promoter-conditional expression system. No posttranslational modification of any of the subunits was detected, although the ratio of polypeptides produced varied with the temperature at which expression occurred. FrdC and FrdD, the membrane anchor polypeptides, assembled rapidly into the membrane and then were capped with FrdA and FrdB in separate events. Truncation of the C-terminal domain of FrdD by insertion of transposon Tn5 into the frdD cistron interfered with membrane insertion of the anchor polypeptides and assembly of the holoenzyme. Proteolytic degradation of truncated FrdD was implicated in the production of a soluble FrdABC trimer.     

DNA polymerase III holoenzyme of Escherichia coli. II. A novel complex including the gamma subunit essential for processive synthesis

Processive DNA synthesis, a property of DNA polymerase III holoenzyme of Escherichia coli, was not achieved by combining the pol III core (alpha, epsilon, and theta subunits) and the beta and gamma subunits. An activity that restored processivity to these subunits was found in crude extracts and was overproduced 4-fold in cells with plasmids amplifying the tau and gamma subunits. Purified to homogeneity, the activity, assayed by reconstitution of processivity, was represented by five polypeptides which were copurified. Judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, these correspond to the known subunits gamma (52 kDa) and delta (35 kDa) and to three new polypeptides: delta' (33 kDa), chi (15 kDa), and psi (12 kDa). The five polypeptides form a tight complex with a native molecular weight of about 200 kDa and a subunit stoichiometry of two gamma subunits to one each of the others. Processive DNA synthesis, now achieved with only three components (pol III core, beta, and the auxiliary complex), provides the opportunity to assess the functions of each and the contribution that the remaining auxiliary tau subunit makes to reconstitute a holoenzyme.     

Reconstitution of quinone reduction and characterization of Escherichia coli fumarate reductase activity

Resolution of the fumarate reductase complex (ABCD) of Escherichia coli into reconstitutively active enzyme (AB) and a detergent preparation containing peptides C and D resulted in loss of quinone reductase activity, but the phenazine methosulfate or fumarate reductase activity of the enzyme was unaffected. An essential role for peptides C and D in quinone reduction was confirmed by restoration of this activity on recombination of the respective preparations. Neither peptide C nor peptide D by itself proved capable of permitting quinone reduction and membrane binding by the enzyme when E. coli cells were transformed with plasmids coding for the enzyme and the particular peptides. Transformation of a plasmid coding for all subunits resulted in a 30-fold increase in membrane-bound complex, which exhibited, however, turnover numbers for succinate oxidation and fumarate reduction that were intermediate between the high values characteristic of chromosomally produced complex and the relatively low values found for the isolated complex. It is also shown that preparations of the isolated complex and membrane-bound form of the enzyme, as obtained from anaerobically grown cells, are in the deactivated state owing to the presence of tightly bound oxalacetate and thus must be activated prior to assay.     

Dimethyl sulfoxide reductase of Escherichia coli: an investigation of function and assembly by use of in vivo complementation.

Dimethyl sulfoxide (DMSO) reductase of Escherichia coli is a membrane-bound, terminal anaerobic electron transfer enzyme composed of three nonidentical subunits. The DmsAB subunits are hydrophilic and are localized on the cytoplasmic side of the plasma membrane. DmsC is the membrane-intrinsic polypeptide, proposed to anchor the extrinsic subunits. We have constructed a number of strains lacking portions of the chromosomal dmsABC operon. These mutant strains failed to grow anaerobically on glycerol minimal medium with DMSO as the sole terminal oxidant but exhibited normal growth with nitrate, fumarate, and trimethylamine N-oxide, indicating that DMSO reductase is solely responsible for growth on DMSO. In vivo complementation of the mutant with plasmids carrying various dms genes, singly or in combination, revealed that the expression of all three subunits is essential to restore anaerobic growth. Expression of the DmsAB subunits without DmsC results in accumulation of the catalytically active dimer in the cytoplasm. The dimer is thermolabile and catalyzes the reduction of various substrates in the presence of artificial electron donors. Dimethylnaphthoquinol (an analog of the physiological electron donor menaquinone) was oxidized only by the holoenzyme. These results suggest that the membrane-intrinsic subunit is necessary for anchoring, stability, and electron transport. The C-terminal region of DmsB appears to interact with the anchor peptide and facilitates the membrane assembly of the catalytic dimer.     

Structure of fumarate reductase on the cytoplasmic membrane of Escherichia coli.

The terminal electron transfer enzyme fumarate reductase has been shown to be composed of a membrane-extrinsic catalytic dimer of 69- and 27-kilodalton (kd) subunits and a membrane-intrinsic anchor portion of 15- and 13-kd subunits. We prepared inverted membrane vesicles from a strain carrying the frd operon on a multicopy plasmid. When grown anaerobically on fumarate-containing medium, the membranes of this strain are highly enriched in fumarate reductase. When negatively stained preparations of these vesicles were examined with an electron microscope, they appeared to be covered with knob-like structures about 4 nm in diameter attached to the membrane by short stalks. Treatment of the membranes with chymotrypsin destroyed the 69-kd subunit, leaving the 27-, 15-, and 13-kd subunits bound to the membrane; these membranes appeared to retain remnants of the structure. Treatment of the membranes with 6 M urea removed the 69- and 27-kd subunits, leaving the anchor polypeptides intact. These vesicles appeared smooth and structureless. A functional four-subunit enzyme and the knob-like structure could be reconstituted by the addition of soluble catalytic subunits to the urea-stripped membranes. In addition to the vesicular structures, we observed unusual tubular structures which were covered with a helical array of fumarate reductase knobs.     

Subunit location of the iron-sulfur clusters in fumarate reductase from Escherichia coli

The subunit location of the [2Fe-2S], [3Fe-4S], and [4Fe-4S] clusters in Escherichia coli fumarate reductase has been investigated by EPR studies of whole cells or whole cells extracts of a fumarate reductase deletion mutant with plasmid amplified expression of discrete fumarate reductase subunits or groups of subunits. The results indicate that both the [2Fe-2S] and [3Fe-4S] clusters are located entirely in the iron-sulfur protein subunit. Information concerning the specific cysteine residues that ligate these clusters has been obtained by investigating the EPR characteristics of cells of the deletion mutant amplified with a plasmid coding for the flavoprotein subunit and a truncated iron-sulfur protein subunit. While the results are not definitive with respect to the location of the [4Fe-4S] cluster, they are most readily interpreted in terms of this cluster being entirely in the flavoprotein subunit or bridging between the two catalytic domain subunits. These new results are discussed in light of the amino acid sequences of the two subunits and the sequences of structurally well characterized iron-sulfur proteins containing [2Fe-2S], [3Fe-4S], and [4Fe-4S] centers.     

The effects of anions on fumarate reductase isolated from the cytoplasmic membrane of Escherichia coli.

A broad range of anions was shown to stimulate the maximal velocity of purified fumarate reductase isolated from the cytoplasmic membrane of Escherichia coli, while leaving the Km for fumarate unaffected. Reducing agents potentiate the effects of anions on the activity, but have no effect by themselves. Thermal stability, conformation as monitored by circular dichroism and susceptibility to the thiol reagent 5,5'-dithiobis-(2-nitrobenzoic acid) are also altered by anions. The apparent Km for succinate in the reverse reaction (succinate dehydrogenase activity) varies as a function of anion concentration, but the maximal velocity is not affected. The membrane-bound activity is not stimulated by anions and its properties closely resemble those of the purified enzyme in the presence of anions. Thus it appears that anions alter the physical and chemical properties of fumarate reductase, so that it more closely resembles the membrane-bound form.     

Construction of an active acetohydroxyacid synthase I with a flexible linker connecting the catalytic and the regulatory subunits

Acetohydroxyacid synthase I (AHAS I), one of three isozymes in Escherichia coli catalyzing the first common step in the biosynthesis of branched amino acids, is composed of two kinds of subunits. The large catalytic (B) and small regulatory (N) subunits of the holoenzyme dissociate and associate freely and rapidly and are quite different in size, charge and hydrophobicity, so that high resolution purification methods lead to partial separation of subunits and to heterogeneity. We have prepared several linked AHAS I proteins, in which the large subunit B with a hexahistidine-tag at the N-terminus, was covalently joined by a flexible linker, containing several (X) amino acids, to the small subunit N to form His6-BuXN polypeptides. All linked BuXN polypeptides have similar specific activity, sensitivity to valine and substrate specificity as the wild type holoenzyme. The most successful BuXN linked protein (Bu30N-r) was inserted into and expressed in yeast and its catalytic properties were tested.     

Biosynthesis of membrane-bound nitrate reductase in Escherichia coli: evidence for a soluble precursor.

Membrane-bound nitrate reductase of Escherichia coli consists of three subunits designated as A, B, and C, with subunit C being the apoprotein of cytochrome b, A hemA mutant that cannot synthesize delta-aminolevulinic acid (ALA) produces a normal, stable, membrane-bound enzyme when grown with ALA. When grown without ALA, this mutant makes a reduced amount of membrane-bound enzyme that is unstable and contains no C subunit. Under the same growth conditions, this mutant accumulates a large amount of a soluble form of the enzyme in the cytoplasm. Accumulation of this cytoplasmic form begins immediately upon induction of the enzyme with nitrate. The cytoplasmic form is very similar to the soluble form of the enzyme obtained by alkaline heat extraction. It is a high-molecular-weight complex with a Strokes radius of 8.0 nm and consists of intact A and B subunits. When ALA is added to a culture growing without ALA, the cytoplasmic form of the enzyme is incorporated into the membrane in a stable form, coincident with the formation of functional cytochrome b. Reconstitution experiments indicate that subunit C is present in cultures grown without ALA but is reduced in amount or unstable. These results indicate that membrane-bound nitrate reductase is synthesized via a soluble precursor containing subunits A and B, which then binds to the membrane upon interaction with the third subunit, cytochrome b.     

Nucleotide sequence and gene-polypeptide relationships of the glpABC operon encoding the anaerobic sn-glycerol-3-phosphate dehydrogenase of Escherichia coli K-12.

The nucleotide sequence of a 4.8-kilobase SacII-PstI fragment encoding the anaerobic glycerol-3-phosphate dehydrogenase operon of Escherichia coli has been determined. The operon consists of three open reading frames, glpABC, encoding polypeptides of molecular weight 62,000, 43,000, and 44,000, respectively. The 62,000- and 43,000-dalton subunits corresponded to the catalytic GlpAB dimer. The larger GlpA subunit contained a putative flavin adenine dinucleotide-binding site, and the smaller GlpB subunit contained a possible flavin mononucleotide-binding domain. The GlpC subunit contained two cysteine clusters typical of iron-sulfur-binding domains. This subunit was tightly associated with the envelope fraction and may function as the membrane anchor for the GlpAB dimer. Analysis of the GlpC primary structure indicated that the protein lacked extended hydrophobic sequences with the potential to form alpha-helices but did contain several long segments capable of forming transmembrane amphipathic helices.     

Fumarate reductase is a soluble enzyme in anaerobically grown Shewanella putrefaciens MR-1

Abstract The expression and distribution of fumarate reductase activity was examined in Shewanella putrefaciens MR-1. Fumarate reductase was expressed at very low levels in aerobically grown cell and was markedly induced by growth under anaerobic conditions. Cells were fractionated into soluble and purified membrane components by four different methods. For all four methods used, and in marked contrast to the membrane-bound fumarate reductases of other bacteria, ≧ 98% of the fumarate reductase activity was localized in the soluble fraction. In cells subjected to osmotic shock or treated with lysozyme and EDTA to form spheroplasts, the specific activity of fumarate reductase was highest in the periplasmic fraction, while the majority of total fumarate reductase activity was in the cytoplasmic fraction.     

DNA polymerase III holoenzyme of Escherichia coli. I. Purification and distinctive functions of subunits tau and gamma, the dnaZX gene products

Escherichia coli dnaZX, the gene which when mutant blocks DNA chain elongation, was cloned into a lambda PL promoter-mediated expression vector. In cells carrying this plasmid, the activity that complements a mutant dnaZ extract in replicating a primed single-stranded DNA circle was increased about 20-fold. Two polypeptides of 71 and 52 kDa were overproduced. Upon fractionation, two complementing activities were purified to homogeneity and proved to be the 71- and 52-kDa polypeptides. Immunoassays revealed their respective identities with the tau and gamma subunits of DNA polymerase III holoenzyme. The N-terminal amino acid sequences of the first 12 residues were identical in both subunits, as were their molar specific activities in dnaZ complementation. Thus, the tau subunit complements the defect in the mutant holoenzyme from the dnaZts strain as efficiently as does the gamma subunit. Inasmuch as the 71-kDa subunit (tau) can also overcome the enzymatic defect in a dnaX mutant strain, this polypeptide has dual replication functions, only one of which can be performed by the gamma subunit. Availability of pure tau and gamma subunits for study has provided the basis for proposing an asymmetry in the structure and function of a dimeric DNA polymerase III holoenzyme.     

The narJ gene product is required for biogenesis of respiratory nitrate reductase in Escherichia coli.

Respiratory nitrate reductase purified from the cell membrane of Escherichia coli is composed of three subunits, alpha, beta, and gamma, which are encoded, respectively, by the narG, narH, and narI genes of the narGHJI operon. The product of the narJ gene was deduced previously to be a highly charged, acidic protein which was not found to be associated with any of the purified preparations of the enzyme and which, in studies with putative narJ mutants, did not appear to be absolutely required for formation of the membrane-bound enzyme. To test this latter hypothesis, the narJ gene was disrupted in a plasmid which contained the complete narGHJI operon, and the operon was expressed in a narG::Tn10 insertion mutant. The chromosomal copy of the narJ gene of a wild-type strain was also replaced by the disrupted narJ gene. In both cases, when nar operon expression was induced, the alpha and beta subunits accumulated in a form which expressed only very low activity with either reduced methyl viologen (MVH) or formate as electron donors, although an alpha-beta complex separated from the gamma subunit is known to catalyze full MVH-linked activity but not the formate-linked activity associated with the membrane-bound complex. The low-activity forms of the alpha and beta subunits also accumulated in the absence of the NarJ protein when the gamma subunit (NarI) was provided from a multicopy plasmid, indicating that NarJ is essential for the formation of the active, membrane-bound complex. When both NarJ and NarI were provided from a plasmid in the narJ mutant, fully active, membrane-bound activity was formed. When NarJ only was provided from a plasmid in the narJ mutant, a cytosolic form of the alpha and beta subunits, which expressed significantly increased levels of the MVH-dependent activity, accumulated, and the alpha subunit appeared to be protected from the proteolytic clipping which occurred in the absence of NarJ. We conclude that NarJ is indispensible for the biogenesis of membrane-bound nitrate reductase and is involved either in the maturation of a soluble, active alpha-beta complex or in facilitating the interaction of the complex with the membrane-bound gamma subunit.     

Electron transfer from menaquinol to fumarate. Fumarate reductase anchor polypeptide mutants of Escherichia coli

Fumarate reductase (FRD) of Escherichia coli is a four-subunit membrane-bound complex that is synthesized during anaerobic growth when fumarate is available as a terminal oxidant. The two subunits that comprise the catalytic domain, FrdA and FrdB, are anchored to the cytoplasmic membrane surface by two small hydrophobic polypeptides, FrdC and FrdD, which are also required for the enzyme to interact with quinone. To better define the individual roles of the FrdC and FrdD polypeptides in FRD complex formation and quinone binding, we selectively mutagenized the frdCD genes. Frd- strains were identified by their inability to grow on restrictive media, and the resulting mutant FRD complexes were isolated and biochemically characterized. The majority of the frdC and frdD mutations were identified as single base deletions that caused premature termination in either FrdC or FrdD and resulted in the loss of one or more of the predicted transmembrane helices. Two additional frdC mutants were characterized that contained single base changes resulting in single amino acid substitutions. All mutant enzyme complexes were incapable of oxidizing the physiological electron donor, menaquinol-6, in the presence of fumarate. Additionally, the ability of the mutant complexes to oxidize reduced benzyl viologen or reduce the ubiquinone analogue 2,3-dimethoxy-5-methyl-6-pentyl-1,4-benzoquinone and phenazine methosulfate with succinate as electron donor were also affected but to varying degrees. The separation of oxidative and reductive activities with quinones suggests there are two quinone binding sites in the fumarate reductase complex and that electron transfer occurs in two le- steps carried out at these separate sites.